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AD-A265 033
STUDIES OF GLOBAL IONOSPHERICELECTRODYNAMICS
DTICELECTE
R.A. Heelis MAY 2 5 19931
CUniversity of Texas at DallasCenter for Space SciencesP.O. Box 830688, MS F022Richardson, TX 75083-0688
February 1993
Final Report17 October 1989 - 17 January 1993
Approved for public release; distribution unlimited
._ 93-11609
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1. AGENCY USE ONLY (Leave blank) 12. REPORT DATE 3. REPORT TYPE AND DATES COVERED
February 1993 Final (17 Oct 1989-17 Jan 1993)
4. TITLE AND SUBTITLE S. FUNDING NUMBERS
Studies of Global Ionospheric Electrodynamics PE 61102FPR 2310 TA G9 WU Al
6. AUTHOR(S)
R. A. Heelis Contract F19628-90-K-0001
7. PERFORMING ORGANIZATION NAME(S) AND ADORESS(ES) B. PERFORMING ORGANIZATION
University of Texas at Dallas REPORT NUMBER
Center for Space SciencesP.O. Box 830688, M/S F022Richardson, TX 75083-0688
9. SPONSORING / MONITORING AGENCY NAME(S) AND ADDRESS(ES) 10. SPONSORING' MONITORING
Phillips Laboratory AGENCY REPORT NUMBER
29 Randolph RoadHanscom AFB, MA 01731-3010 PL-TR-93-2025
Contract M.nager: David Anderson/GPIM
11. SUPPLEMENTARY NOTES
12a. DISTRIBUTION / AVAILABILITY STATEMENT 12b. DISTRIBUTION CODE
Approved for public release;Distribution unlimited
13. ABSTRACT (Maximumr200words) The distribution of ionospheric plasma in the F layer isintimately related to the electrodynamics of the region. In order to understandmany of the morphological features of the plasma, it is necessary to study both thecomposition and the motion of the plasma both parallel and perpendicular to themagnetic field. At low and middle latitudes we examine various contributions to theelectric field, producing plasma motions perpendicular to the magnetic field, andassess their relative importance as functions of latitude and magnetic activity.
Understanding the distribution of ion species in the topside equatorial ionospherealso requires consideration of these ion drifts. At higher latitudes, where electri(field sources from the inner and outer magnetosphere must be considered, the perpen-dicular ion drifts can be very large and result in frictional heating of the plasma.This heating produces large scale motion along the magnetic field line that is aninherent part of the plasma circulation in the region. Finally, studies here show
that small scale structures in the plasma concentration and electric field at highlatitudes are also important in assessing the energy budget and often dominates theelectrodynamics of the region.
14. SUBJECT TERMS 15. NUMBER OF PAGES
Ionospheric Drifts 24Ionospheric Composition 16. PRICE CODEElectrodynamics
17. SECURITY CLASSIFICATION 18. SECURITY CLASSIFICATION 19. SECURITY CLASSIFICATION 20. LIMITATION OF ABSTRACTOF REPORT OF THIS PAGE OF ABSTRACT
Unclassified Unclassified Unclass.ified SAR";.SN 7540-01-280-i5 00 Standard Porm 298 (Rev 2-89)
01,1,'104m•N Ov AN',, StaI Zlq-'S
TABLE OF CONTENTS
Page
1. Introduction ..................................................................................................... 1
2. The High Latitude Ionosphere
2.1 O verview ................................................................................. 1
2.2 Three-Dimensional Considerations ............................................... 4
2.3 The Mid-Latitude Trough ............................................................. 6
2.4 Energy Dissipation in Electrodynamic Structures ..........................
3. The Low and Middle Latitude Ionospheric Composition .......................... 9
4. Low and Middle Latitude Electrodynamics .................................................... 11
R eferences ............................................................................................ 14
5. Publications ................................................................................................ 15
NTIS CRAMIA 0 I1C TA13
UnannoncedJustification..
"1B1Distribution I
A. J01abi:4t Cotles
S'Avail ano Ior
, Dst Special
STUDIES OF IONOSPHERIC ELECTRODYNAMICS
1. Introduction.In the F-region ionosphere the transport of plasma perpendicular to the magnetic field is an
extremely important factor effecting its composition, temperature and concentration. The
electric fields that produce this ExB drift motion of the plasma originate both inside and outside
the ionosphere itself. Inside the ionosphere electric field are produced by dynamo action of the
neutral atmosphere. Outside the ionosphere, electric fields produced in the plasma sheet, the low-
latitude boundary layer and the magnetosheath, are mapped along magnetic fields lines from
their source to the ionosphere. The work described here is devoted to a stud" of these electric
fields in an attempt to understand their variability and the effects that this variability can have on
the ionospheric plasma itself.
The electric fields that we are studying have an entire spectrum of spatial and temporal scale
sizes that behave differently. At large scale sizes, at low and middle latitudes, electric fields map
almost unattenuated along magnetic field lines. Stidies in this area thus reveal the properties of
the source themselves as well as the ionospheric response. At high latitudes even the larger scale
electric fields may be associated with significant field-aligned currents. Thus information about
the source can be modified. However a characterization of the local field and the response of the
ionosphere can be achieved. At small scale sizes, the mapping properties of the field throughout
the ionosphere become important and this represents the first level of understanding that must be
achieved.
The research activities reported on here, represent some significant advances in
understanding the generation and mapping of electric fields in the ionosphere. We have provided
descriptions of large scale climatological features of the ionosphere as well as some details of
physical processes that are responsible for some of the observed features.
2. The High Latitude Ionosphere.2.1 Overview
At high latitudes the ionospheric plasma is dominated by ExB drifts that originate in theouter magnetosphere. Here, electric field sources that originate in the magnetosheath and in the
low-latitude boundary layer have signatures of ionospheric convection that behave quite
differently as the interplanetary magnetic field changes. Interpretation of observations seems to
require consideration of both sources but we are unable, at present. to determine the relative
importance of these sources in any particular circumstance. Figure 1 summarizes the magnetic
field and ionospiieric circulation consistent with an electric field originating in the low-latitude
I
6/ /
18
Figure 1: Magnetic field configuration and ionospheric convection pattern forconnection to the low-latitude boundary layer.
boundary layer. We note that in this picture a two-cell circulation of plasma in the ionosphere is
associated with a similar circulation in the boundary layer and the plasma sheet. Assuming that
the frozen in flux concept is enforced everywhere, then all the antisunward flowing magnetic
flux in the boundary layer must return sunward in the polar cap. However, violations of this
concept would allow this not to be the case but still remain essentially consistent with the
indicated ionospheric flow. When the IMF has a southward component the manner in which the
geomagnetic field and the IMF are interconnected is quite well understood and the electric field
derived from the magnetosheath and transferred to the ionosphere is well specified. Figure '
shows this interconnection and the resulting circulation of plasma in the plasma sheet, the
magnetosheath, and the ionosphere. In this case the frozen in flux concept is clearly violated on
the dayside and on the nightside where the ionospheric plasma makes a transition from closed to
open field lines and from open to closed field lines respectively. There is thus no requirement for
the antisunward and sunward magnetic fluxes to match except in an average sense.
The electric field from the magnetosheath should clearly be dependent on the orientation of
the IMF while it is not so obvious that the low-latitude boundary layer flow should have such a
sensitivity. Thus examination of how the ionospheric flow changes as the IMF changes can shed
some light on the importance of these different sources. A problem in this area is related to
defining how the interconnection between the IMF and the geomagnetic field might occur when
the IMF is northward. Figure 3 shows one possibility in which interconnection is made on
geomagnetic field lines that stretch own the nightside tail of the magnetosphere. In this case the
ionospheric plasma stills circulates in a two-cell convection pattern but the sense of circulation is
reversed. Studies have shown that sunward flow at very high latitudes is a ubiquitous feature of
the ionospheric plasma when the IMF is northward. However, studies also show that a simple
2
1 2 3
6
3 Ionosphere
"122
• '•; t24
1 23
Z -W .-0 3
6 5 Plasma Sheet2
1 8 21
Figure 2: Magnetic field configuration and ionospheric convection pattern forconnection to a southward interplanetary magnetic field.
two-cell convection pattern, such as that shown in figure 3, is rarely observed. In fact the most
commonly observed feature of the convection pattern can only be explained by including an
electric field source from the low-latitude boundary layer. In the most simple of pictures this
would lead to a four-cell pattern with the convection cells driven from the boundary layer
surrounding, at dawn and dusk, the convection cells from the magnetosheath. However. it is
reasonable to also consider the evolution of the pattern as the IMF changes and such
considerations lead to the expectation that the ionospheric convection pattern could show
considerably more structure than is indicated in figure 3 [Heelis. 19911.
3
6
4 5
S12 2 16 24
44
2 3\j
Figure 3: Magnetic field configuration and ionospheric convection pattern forconnection to the a northward interplanetary magnetic field.
2,2 Three-Dimensional Considerations.
In addition to the circulation of ionospheric plasma perpendicular to the magnetic field.
motions along the magnetic field may also effect the composition and concentration observed at
any given location. These field-aligned motions are coupled to the perpendicular motions in two
ways. First, the perpendicular motion can transport plasma through regions of ionization
production and heating by energetic particles. This leads to plasma expansion above the F-peak.
Second, the rapid horizontal motion of the plasma itself can result in frictional heating in the F
region and subsequent plasma loss by enhanced chemical recombination. This can lead first to
plasma expansion and then to plasma decay. It should be evident therefore that plasma
circulation in the F-region is essentially a 3-dimensional concept. As plasma convects through
the dayside cusp region it is heated by precipitating electrons, the ionization rate increase due to
these same electrons, and the plasma may be frictionally heated by large horizontal drifts. All
these processes produce expansion of the plasma as it assumes a new scale height consistent with
the heating and production rates. On exiting the cusp region and flowing antisunward, all these
processes essentially cease and the plasma relaxes to its former state. In doing'so the topside
plasma falls to re-establish a smaller scale height. The plasma subsequently flows into the
nightside auroral zone where it may again be heated by rapid drifts and energetic particle
precipitation.
4
Figure 4 shows contours of the field-aligned drifts measured by Dynamics Explorer-2 at
northern high latitudes in the altitude region between 350 km and 600 km tHeelis et al., 19921.
12
- / f \
N, /
f," 1'-',.,/ ,"
8 , ." ,• • ... 7 ••; , \
"\ N• \, ' ,. - . ,
MIN MAXKP 0 99 " -ax -999 999B 999 500 ILATBZ -g99 a " "ALT 400 800
00
Figure 4: Contours of fieid-aligned ion drift near 400 km altitudeobserved by DE-2 in the Northern Hemisphere.
Field-aligned ion drift velocities with average magnitude of about 50 ms"I are seen throughout
the high latitude region and transport ion fluxes of 1013 m' 2 s" 1 both upward and downward
along the magnetic field lines. The upward velocities are confined to the auroral zones where
frictional heating and heating by low energy electrons is believed to be responsible for the
maximum velocities appearing on the dayside and in the cusp region. In the polar cap. where
frictional heating is low and energetic electrons are largely absent, the ion drifts are downward.
Downward velocities can extend into the nightside auroral zones, but structure in the horizontal
ion drift and in the energetic particle precipitation leads to frequent observation of upward drifts
at this location. On average the nighttime auroral zone flows are upward with an average
magnitude of 30 ms"1. On average a net outward flux is observed to leave the high-latitude
ionosphere above 400 kin. This outflow of 8 x 1025 s-l is comparable to the energetic ion
outflow, apparently of ionospheric origin, observed by DE-I during the same period.
Ionospheric ions move upward as they move sunward in the auroral zones. Some fraction of this
upward moving population is apparently energized to escape energy by processes that are not
discussed here. They continue to convect antisunward in the polar cap and are seen leaving the
5
ionosphere by DE-1. The remainder fall in the topside ionosphere as it cools due to the
cessation of particle and frictional heating. This cycle then repeats as the antisunward flowing
ions return towards the sun in the nightside auroral zone.
2.3 The Mid-Latitude Trough
One region, just outside the main influence of the high-latitude convection pattern is the
mid-latitude trough. This region is of particular interest since large fluxes of ions are frequent!
observed to be moving upward associated with rapid sub-auroral ion drifts (SAID).
This association between the horizontal and field-aligned plasma flows has been used to
explain both the plasma features and the dynamics in the mid-latitude trough. Anderson et al.
[1991] claim that the large upward velocities sometimes seen in the topside ionosphere of the
mid-latitude trough are due to the expansion of the plasma associated with frictional heating.
They further claim that this expansion is an important factor in determining the ion concentration
that is observed in the trough itself. Calculations by Sellek et al. [. 9911 have shown that field-
aligned flows of the appropriate magnitude can indeed be induced by large horizontal flows.
Gombosi and Killeen [1987] have investigated the ability of typical frictional heating rates to
provide the 0+ plasma with escape energy and more recently Moffett et al. [19921 havedescribed the response of the topside ionosphere to the sudden onset of rapid horizontal drifts
exceeding 1 km s-1 .
n 1800- 1000km a) b)
1400- 0kmk
> 1000-
40 20
0 0 1 3 0 .0 k m 1 0 0 k i n. .
0 10 20 30 0 10 In 30
Elapsed Time (minutes) Elapsed Times (mins)
Figure 5: Field-aligned drifts in SAID events of 2 Im/s with acceleration tunes ofa) 15 secs and b) 10 mins.
The calculations that we have performed expose the sensitivity of the observed field-aligned ion
drifts to the onset time scale of the SAID event itself. Figurt. 5 shows the field-aligned drifts and
6
that result when the plasma in the trough region is accelerated to 2 km s-1 in 15 secoids and in
10 minutes. The dramatic changes in the maximum field-aligned drift is apparent. Our work
suggests that in the presence of a large horizontal ion drift velocity the major factors affecting the
energy budget of the plasma can be summarized as follows. In the electron gas collisions with
the ions provide a heat source below about 600 km altitude and conduction heats the electrons
above this altitude. Above about 1000 km altitude efficient heat conduction in the electrons
produces a temperature that is in excess of the ions. Thus ion-electron collisions provide a heat
sink for the electrons in this region. In the ion gas below about 700 km altitude, frictional
heating of the ions is the dominant heat input and this is countered by collisional cooling to the
neutral gas. Above about 800 km advective transport of hot plasma from lower altitudes
dominates the temperature increase. This is a transient phenomena that exists vhile the plasma
attains a new scale height. After that the relatively small contributions of heat conduction in the
ions and collisional heating and cooling to the electrons determine the time evolution of the ion
temperature.
The above discussion highlights three factcs that affect the variability in the field-ali gned
flows. First, the magnitude of the SAID velocity affects the initial magnitude of the plasma
pressure gradient formed in the frictional heating region between 400 km and 600 km. Second.
the resulting plasma expansion is a transient phenomenon in an F-region flux tube and thus the
time of the observation with respect to the onset of the SAID event will effect what part of the
transient history is observed. Finally, since the field-aligned flow itself redistributes the heat and
changes the field-aligned pressure gradients, the time taken by the plasma to reach the observed
SAID velocity is important in determining the maximum field-aligned flows 0hat take place.
Observations of SAID events [Anderson et al., 1991] do not allow a reliable determination
of the onset time scale except to establish that it is less than 45 minutes. SAID events can be
maintained over time scales of several hours. Even if the onset of the event is instantaneous. the
very large peak velocities associated with this short onset time will only be experienced by the
plasma already in the SAID location. The onset time for all subsequent plasma will depend upon
the convective configuration of the SAID event and not on its initial onset time scale.
Observations of the ion drifts associated with a SAID [Spiro et al., 19781 suggest that the plasma
enters the westward convection in the SAID region from lower latitudes after flow eastward and
poleward. The poleward velocities just equatorward of the SAID are quite small, typically less
than 100 m s-1, and even for a SAID half-width of 0.50 (-50 kin), it would take -10 minutes for
the maximum SAID velocity to be reached. The evolution of the plasma described in our second
scenario is therefore likely to be more representative of observed conditions. In the rest frame of
the plasma, the field-aligned drift associated with SAID onset is a transient phenomenon. It
7
continues only until advection acts to reduce the altitude gradient in the ion temperature which is
responsible for a plasma pressure gradient producing the field-aligned drifts. However.
observationally the field-aligned drift is not a transient feature. New plasma is continuously
convecting into and through the SAID region and thus the transient conditions modeled here will
be continuously observed at any fixed location in the SAID region. Observations taken where
the plasma enters the SAID region will continuously record peak velocities of the magnitude
calculated here. Where the plasma has resided in the SAID region for some time, much smaller
velocities will be continuously observed. The peak velocities may be considerably smaller than
those shown here. Further calculations in which the time scale for achieving the maximum SAID
velocity was 20 minutes show peak field aligned drifts at 750 km altitude of only 400 m s-
2.4 Energy Dissipation in Electrodynamic Structures.
Electromagnetic energy is dissipated in the ionosphere in two ways. One as heat and another asEnergy Dissipation below 600 km in Polar Cap momentum in the neutral gas. The heating
C 0002 rate is proportional to the square of the ion-
*neutral velocity and the Pedersen conductivity
while the rate of change of the momentum is
-0o001 linearly proportional to this same velocity
difference and the Pedersen conductivity.
Thus most of the energy is dissipated as JouleS, heating. However, when considering the
,0 0o• , magnitude of this energy dissipation it Is
Log Scale Size(km) important to consider where the heat is
Energy Dissipation below 600 km in Auroral Zone dissipated. Since the mappirg properties of0.008 the electric field that moves the ions are
o Perpendicufar dependent on the scale size of the structure the0006 Parallel
heating rate is dependent on an effective0
a 0004 Pedersen corductivity and not the more
commonly used height -integrated quantity
0002-• • [Heelis and Vickrey, 19911. The scale-size'" , dependent mapping properties of electric
0.0001 fields take into account the attenuation in theLog Scale Size (km) electric field along the magnetic field lines.
Figure 6: The scale size dependence of energy Thus for electric fields that do not map there isdissipation from parallel and perpendicularcurrents in the polar cap and auroral zone. dissipation of the electromagnetic energy both
parallel and perpendicular to the magnetic
8"
field lines. The perpendicular dissipation is specified by taking into account the effective flux
tube integrated Pedersen conductivity. lhe parallel dissipation must be accounted for separately
Figure 6 shows the distribution of energy dissipation rates perpendicular and parallel to the
magnetic field for a range of different scale sizes and two different ionospheric conductivity
distributions describing the polar cap and the auroral zone.
The results demonstrate that an accurate description of t.i, energy dissipation from quasi-
static electric fields at high latitudes must include consideration of both the perpendicular and
parallel currents. These considerations may be important for perpendicular velocity gradients of
0.5 s-1 or greater in the auroral zone. For the simple fixed number density profiles considered
here, the parallel and perpendicular electric fields are related through their scale size and the
altitude distribution of the Direct and Pedersen conductivities. As one would expect, the largest
parallel electric fields occur near 200 km where the Pedersen conductivity has a steep gradient
with altitude as does the ratio of Direct to Pedersen conductivity. For sufficiently large field-
aligned currents, significant field-aligned potential differences occur above 200 kmi. Even when
these fields are small compared to the ambipolar electric field they can cause about 30"% of the
energy dissipation to occur from currents parallel to the magnetic field rather than perpendicular
to it. The principal significance of this repartitioning of the energy dissipation between
perpendicular and parallel current components lies in the difference in altitude where the
respective dissipation profiles peak. The perpendicular dissipation dominates at low altitudes
where ion-neutral collisions provide the dissipative mechanism, whereas parallel current energy
dissipation occurs at higher altitudes through !lectron-ion collis.ons. While a quantitative
estimate of the total energy dissipated may be obtained by assuming that it all occurs
perpendicular to the magnetic field and that the electric field maps unattenuated throughout the
ionosphere, it should be emphasized that this is an erroneous description of the physical situation
for velocity gradients of the order of 0.5 s-1 or greater, Such velocity gradients, associated with
large amplitude quasi-static convection electric fields, can be commonplace in the high latitude
ionosphere. The simple illustrative calculations performed should be viewed cautiously when
the perpendicular ion velocity gradients are very large because the field-aligned electric fi--lds
can be large enough that their effect on the ambient plasma distribution should be taken into
account.
3. The Low and Middle Latitude Ionospheric Composition
At low and middle latitudes the ionospheric composition and concentration and the
ionospheric motion are intimately coupled. The ExB drift motion of the plasma depends
dramatically on the distribution of the ionospheric conductivity. but this distribution is itself
dependent on the ExB drift motion. In order to unravel some of the complex coupling processes
9
it is necessary to understand the response of the ionosphere to known ExB drift motions and to
understand the circumstances under which these motions change.
A sensitive monitor of the ExB drift motion of the plasma is the height of the peak and the
concentration at the peak of the F layer. The behavior of the F-layer peak also effects the
distribution of ionospheric species in the topside ionosphere. Klowledge of the topside
ionospheric composition can be obtained from satellite data which provide detailed latitude and
local time distributions of the ionospheric species at a given altitude. Such a study was
undertaken using data from Atmosphere Explorer taken during under solar minimum conditions.
Figure 7 shows the average daytime and nighttime distributions of the ionospheric species
obtained from this study [Gonzalez et al., 1992]. In the ionosphere H+ is produced primarily by
the resonant charge exchange process with 0+ and neutral hydrogen. During the daytime this
AE-E 1975-76 Average ion concentrations for all longitudes.December Solstice Equin,:.;.es June Sotstice
d a y I -e""S* ×0 x_ x ',,oo- Xo H' XH- :
1000 C
800f
S600-
< 400-
100 - 0"xx -x ,!,,
2 00night 41- Hl' q -
=X M,
1000- 1 On,-0 0' 00'
?00
S600
102 WO 10', 102 104 10o6 102 1 o 0
Ion Concentration (cm'3)
Fi~gure 7: Dadytime and Nightime altitude profiles of ionospheric composition obtainedby AE-E at different seasons.
I0
process is a sink for 0+ in the topside ionosphere and the equilibrium concentrations produce an
0+/H+ transition height near the H+ peak. For the solar minimum conditions prevailing during
this period the transition height lies between 750 km and 825 kmn. At night the 0+ concentration
in the bottomside decays due to recombination. Then the H+ stored in the topside during the days
fall to lower altitudes and the charge exchange reaction becomes a source for 0+, The transition
height is lowered to between 550 and 600 km under these conditions.
The 0+ peak concentration changes by about an order of magnitude from day to night, having a
daytime value near 106 cm-3. During solar minimum conditions the F-region ExB drifts have
almost a sinusoidal local time distribution. The lack of a post-sunset enhancement in the ExB
drift means that the average altitude of the daytime and nighttime peak densities are about the
same. In this case the peak altitude remains near 350 km. At solar minimum He+ is always a
minor ion. The transport of this species will be dominated by the 0+ motion and thus a small
seasonal variation is seen in this species as well as in the 0+.
4. Low and Middle Latitude Electrodynamics
Satellite observations can also be used to study the ExB drift motion of the plasma. Studies
of this parameter reveal the dominant local time variations that exist at different latitudes and
enable a qualitative determination of the relative importance of different sources for the electric
fields. At mid-latitudes the ionospheric plasma drift perpendicular to the magnetic field can be
effected by electric fields generated by the dynamo action of the neutral atmosphere in the E
region and the F region, and by electric fields generated in the magnetosphere by the interaction
of the solar wind with the geomagnetic field. The electric field of magnetospheric origin may
manifest itself in two ways that we will term direct electrical influence and mechanical influence.
The mechanical influence results from the so-called "disturbance dynamo" [Blanc and
Richmond, 1980] produced by frictional and particle heating in the auroral zones. The
subsequent motion of the neutral gas is equatorward and westward, by virtue of the angular
momentum carried by the gas (i.e. Coriolis force). Depending on the altitude range over which
the auroral zone heat source is applied, the disturbance dynamo may exist in the E-region and/or
the F-region. In either case the ion drift motion that it produces is predominantly westward at all
local times. Calculations by Blanc and Richmond [19801 indicate that a local maximum in the
westward ion drift of about 100 ms-I might be expected between 40o and 50o magnetic latitude
but this is evidently dependent on the magnitude and location of the auroral zone heat source that
is assumed. The effects of the disturbance dynamo may also be seen for large fractions of a day
following substantial auroral zone heating effects associated with magnetic activity. The
electrical influence of the magnetosphere solar wind interaction at mid-latitudes can be viewed in
II
two ways. first, due to inadequate shielding by the currents in the plasma sheet fJaggi and
Wolf, 19731, the electric field may penetrate or leak inside the plasmasphere. Second the
plasmasphere itself, which is normally free of large fields from the magnetosphere, may contract
to relatively low latitudes during magnetically active times and thus the mid-latitude region may
be directly subject to the fringes of the auroral zone electric field. In the latter case we would
expect that the local time distribution of the electric field to be similar to that seen in the aurora]
zone. In the other case the effects of conductivity gradients between the auroral zone and the
plasmasphere must be taken into account [Senior and Blanc. 1984a].
The behavior of the mid-latitude ionospheric drift has been extensively studied using ground
based radar data from St Santin [Blanc and Amayenc, 19791 and Millstone Hill [Wand and
Evans, 1981]. Additional data describing the dynamo fields at mid-latitudes is also available
from the Arecibo radar in Puerto Rico [Ganguly, et al., 19871 and the MU radar in Japan [Fukao.
et al., 1991; Oliver, et al., 19881.
In addition to observational studies of the mid-latitude drifts, further advances in the
determination of magnetospheric fields at mid-latitudes have been made utilizing numerical
models with varying degrees of sophistication. These models [Spiro and Wolf. 1984. Senior and
Blanc, 1984b)] show that the penetration of the magnetospheric field equatorward of the aurora]
zone x:esults in a different local time distribution of the east-west drift than would be found in the
auroral zone itself. A study by Blanc [1983] suggests that penetration fields and disturbance
dynamo fields may both contribute to the observed drift signatures and that careful evaluation of
the local time effects of each is necessary to separate them.
This work was devoted to describing the latitudinal and local time distributions of the east
west drift observed by DE 2 equatorward of the auroral zone. By examining the distributions
during quiet and disturbed times and contrasting them with the findings of other observational
and theoretical studies we are able to assess the influence of solar dynamo fields and electric
fields from magnetospheric sources. Figure 8 provides the comparison of data from various
sources including that generated by this work [Heelis and Coley, 1992].
We have examined the zonal ion drifts observed by DE 2 during magnetically quiet and
disturbed periods defined by levels of Kp. It is evident that division of the data using this
parameter does not include or exclude magnetospheric effects from a particular latitude. Rather
the magnetospheric effects are modulated by this division. Determination of the local time
distribution of zonal ion drifts from DE 2 necessarily mixes season and local time. Despite these
limitations there are many areas of agreement between the features observed in this data and
those described in data obtained from ground based radars.
It is apparent that explanation of the observed features in the local time and latitude
variations in the zonal ion drifts seen by DE 2 requires both tidal motion of the neutral
12
atmosphere and magnetospheric sources to be included at different locations and under different
conditions. In considering magnetospheric sources, three local time distributions associated with
OE-2/Radw Zonal Ion DrIfts DE.2bdw Zo" io DrIftsArecibo. MU Guist Thes Agecr o, MU C'-turgbd TIms
•"120 120
- --'-ke,- O 0.&W (Ga"a It AL 987 - -- OE-AMao Giso jz at & #
-40- -40-
0-800 3 S. 9 12 15 IS 21 24 0 3 6 9 12 1- 18 21 24
Local Time (hrs) Local Time (brs)
DE-2am1ad•r Zonal Ion Drifts DE.2/Rader Zonal Iom Drifts
St-Smntin Millstone Hill120 120-
S_ .- $--1 Su• w. tw m arm 4rayNer T9?71 - 6 - Stont HS S ixq WAoNd 61•1
a- 0 - -- Sarlin DMtumsa ila 19830 80 - .- M.--tstonse ý aI FW & W Sa. i'- 0- DE-2 q< < ,7 DE*2 3E stt- -" 'DE.2 d*s*.t
,40 - -------.- 40-
00 0 \ ,- " -- 0 -,. - >- _./.'
m 80 ~~~~40 iI'ii"'
0 3 6 9 12 15 18 21 24 0 3 6 9 12 15 11 21 24
Local Time (hrs) Local Time (hrs)
Figure 8: The local time distribution of zonal ion drifts observed by DE-2and different ground stations.
the auroral zone field itself, penetration of the field equatorward of the auroral zone and the
magnetospheric disturbance dynamo must all be accounted for: These latter two sources are not
just present during disturbed times and dominate the local time distribution at latitudes between
450 and 550 even during quiet times as defined here by Kp _ 2. At latitudes above 500, during
disturbed times defined by Kp >_ 3, the expansion of the auroral zone can directly influence the
zonal ion drift observed.
The influences of the electric field sources can be summarized as follows.
1. Semidiumal and terdiumal tides are most important during quiet times between 250 and 550
magnetic local time.
2. The influence of the disturbance dynamo and magnetospheric penetration field are seen on
average down to 450 during quiet times and down to 350 during disturbed times.
3. Direct influence of the auroral zone electric field is important on average down to 600
during quiet times and down to 500 during disturbed times.
13
References
Anderson, P. C., W. B. Hanson, and R. A. Heelis, The Ionospheric Signatures of rapid sub-auroral ion drifts, J. Geophys. Res, 96, 5785-5792, 1991.
Blanc, M., Magnetospheric convection effects at mid-latitudes 1. Saint-Santin observations, J.Geophys. Res., 88, 211-223, 1983.
Blanc, M., and P. Amayenc, Seasonal variations of the ionospheric ExB drifts above Saint-Santinon quiet days, J. Geophys. Res., 84, 2691, 1979.
Blanc, M., and A. D. Richmond, The ionospheric disturbance dynamo, J. Geoph'ys. Res., 85,1669, 1980.
Fukao, S., W. L. Oliver, Y. Onishi, T. Takami, T. Sato, M. Yamamoto, and S. Kato, F regionseasonal behavior as measured by the MU radar, J. Atmos. Terr. Phys., 53, 599. 1991.
Ganguly, S., R. A. Behnke, and B. Emery, Average electric field behavior in the ionosphere overArecibo, J. Geophys. Res., 92, 1199-1210, 1987.
Gombosi, T. I., and T. L. Killeen, Effects of thermospheric motions on the polar wind: A timedependent numerical study, J. Geophys. Res., 92, 4725, 1987.
Gonzalez, S. A., B. G. Fejer, R. A. Heelis, and W. B. Hanson, Ion composition of the topsideequatorial ionosphere during solar minimum, J. Geophys. Res., 97, 4299-4303, 1992.
Heelis, R. A., The high latitude ionopspheric convection pattern, J. Geomag. Geoelec., 43.Suppl., 245-257, 1991.
Heelis, R. A., W. R. Coley, M. Loranc, and M. R. Hairston, Three dimensional ionosphericplasma circulation, J. Geophys. Res., 97, 13903-13910, 1992.
Heelis, R. A., and J. F. Vickrey, Energy dissipation in structured electrodynamic environments,J. Geophys. Res., 96, 14189-14194, 1991.
Jaggi, R. K., and R. A. Wolf, Self consistent calculation of the motion of a sheet of ions in themagnetosphere, J. Geophys. Res., 78, 2852-2866, 1973.
Moffett, R. J., R. A. Heelis, R. Sellek, and G. J. Bailey, The temporal evolution of theionospheric signatures of sub-auroral ion drifts, Planet. Space Sci., 40, 663-670. 1992.
Oliver, W. L., S. Fukao, T. Sato, T. Tsuda, S. Kato, I. Kimura, A. Ito, T. Saryou. and T. Araki.Ionospheric incoherent scatter measurements with the MU radar: Observations of F-regionelectrodynamics., J. Geomag. Geoelectr., 40, 963-985, 1988.
Sellek, R., G. J. Bailey, R. 1. Moffett, R. A. Heelis, and P. C. Anderson, Effects of large zonalplasma drifts on the subauroral ionosphere, J. Atmos. Terr. Phys.. 53, 557-565. 1991.
Senior, C., and M. Blanc, Convection in the inner magnetosphere: Model predictions and data.,Ann. Geophysicae., 5,405-420, 1984.
14
Senior, C., and M. Blanc, On the control of magnetospheric convection by the spatial distributionof ionospheric conductivities, J. Geophys. Res., 89, 261-284, 1984.
Spiro, R. W., R. A. Heelis, and W. B. Hanson, Ion convection and the formation of the mid-latitude F region ionization trough, J. Geophys. Res., 83, 4255-4264, 1978.
Spiro, R. W., and R. A. Wolf, Electrodynamics of convection in the inner magnetosphere, inMagnetospheric Currents, vol. 28,T. A. Potemra, Eds., Am. Geophys. Union. Washington,DC, 1984,.
Wand, R. H., and J. V. Evans, Seasonal and magnetic activity variations of ionospheric electricfields over Millstone Hill, J. Geophys. Res., 86, 103, 1981.
5. Publications
The previously described work has provided the opportunity to both advance our
understanding of the dynamic ionosphere and to distribute our findings to the community. This
report attempts to summarize the work that has been lead by scientists at the University of Texas
at Dallas. In addition a number of collaborative efforts have been undertaken with significant
progress. In all 9 publications have appeared or will appear from these efforts. The following
pages contain the abstracts of these papers all of which contain more detailed information on the
topics discussed.
Anderson, P. C., W. B. Hanson, and R. A. Heelis, The Ionospheric Signatures of rapid sub-auroral ion drifts, J. Geophys. Res, 96, 5785-5792, 1991.
Gonzalez, S. A., B. G. Fejer, R. A. Heelis, and W. B. Hanson, Ion composition of the topsideequatorial ionosphere during solar minimum, J. Geophys. Res., 97, 4299-4303, 1992.
Heelis, R. A., The high latitude ionopspheric convection pattern, J. Geomag. Geoelec.. 43.Suppl., 245-257, 1991.
Heelis, R. A., and W. R. Coley, East-west ion drifts at mid-latitude observed by DynamicsExplorer-2, J. Geophys. Res., 97, 19461-19469, 1992.
Heelis, R. A., W. R. Coley, M. Loranc, and M. R. Hairston, Three dimensional ionosphericplasma circulation, J. Geophys. Res., 97, 13903-13910, 1992.
Heelis, R. A., and J. F. Vickrey, Energy dissipation in structured electrodynamic environments.J. Geophys. Res., 96, 14189-14194, 1991.
Lu, G., P. H. Reiff, T. E. Moore, and R. A. Heelis, Upflowing ionospheric ions in the auroralregion, J. Geophys. Res., 97, 16855-16863, 1992.
Weber, E. J., J. F. Vickrey, H. Gallagher, L. Weiss, C. J. Heinselman, R. A. Heelis, and M. C,Kelley, Coordinated radar and optical measurements of stable auroral arcs at the polar capboundary, J. Geophys. Res., 96, 17847-17863, 1991.
15
JOURNAL OF GEOPHYSICAL RESEARCH. VOL. 96. NO. A4. PAGES 5785-5792. APRIL I 101
The Ionospheric Signatures of Rapid Subauroral Ion Drifts
P. C. ANDERSON, 1 R. A. HEELIS, AND W. B. lIANSON
Center for Space Sciences, Phystc, Programs, University of Teras at Dallas. Richardson.
Subauroral ion drifts (SAID) are latitudinally narrow regions of rapid westward iondrift located in the evening sector and centered on the equatorward edge of the diffuseaurora. Observations of SAID as identified by the ion drift meters on the AtmosphereExplorer C and Dynamics Explorer B spacecraft are utilized to determine their effect onthe F region ion composition, their relationship to the mid-latitude trough, and theirtemporal evolution. At altitudes near the F peak a deep ionization trough is formed inregions of large ion drift where the O± concentration is considerably depleted and the NO'concentration is enhanced, while at higher altitudes the trough signature is considerahlymitigated or even absent. SAID have been observed to last longer thani 3l nuii but Iessthan 3 hours, and their latitudinal width often becomes narrower as time progresses. Theplasma flows westward equatorward of the SAID and becomes more westward as invarianmlatitude increases. Poleward of the SAID, the flow is, on average, westward throughoitthe auroral zone in the evening, while near midnight it becomes eastward
JOURNAL OF GEOPHYSICAL RESEARCH. VOL- 97. NO. A4- PAGIKS 4YJ-•W• "I'RII. I9'iZ
Ion Composition of the Topside Equatorial IonosphereDuring Solar Minimum
S. A. GONZALEZ AND B. G. FEJERCeInter for Atmospheric and Space Sciences, Utah State University, Logan
R. A. HEELIS AND W. B. HANSONCnter for Space Sciences, Physics Programs, University of Texas at Dallas, Richardson
We have used observations from both the Bennett ion mass spectrometer and the retarding potentialanalyzer on board the Atmosphere Explorer E satellite to study the longitudinally averaged O÷. H+. and He+concentrations from 150 to 1300 k- in the equatorial ionosphere during the 1975-1976 solar minimum. Ourresults suggest that the ion mass spectrometer measurements need to be increased by a factor of 2.15 to agreewith the densities from the retard ng ptential analyzer and with gn md-based measurements. The peak H+concentrations are about 2.5 x 10 cm" during the day and 104 cm at night and vary little with season. TheO+/H.+ transition altitude lies between 750 and 825 km during the day and between 550 and 600 km at night.He+ is a minor spcies at all altitudes; its concentration is highly variable with a maximum value of about 103cm' 3 during equinox daytime.
16
J. Geomag Geoeiectr. 43. Supp[ . 245 257, 19YI
The High Latitude Ionospheric Convection Pattern
R. A, HEELIS
Center jor Space Sciences. Physics Prog.rams. Universir, of Texas at Dallas. Raujhardson. iT' aN, I S 4
(Received September I. 1990: Revised March 18, 1991
Simple examination of models of the magnetic and electric field indicate thatboth direct connection with the interplanetary field and connection to the low-latitude boundary layer flow are required to explain many of the repeatable features inthe observations of high latitude ionospheric motions. During times of southwardIMF, these two sources of the electric field may not be easily discernitble and duringtime of northward IMF the details of the magnetic field geometry are important indetermining the geometry of the ionospheric convection cells. When both thesesources of the electric field are considered, a transition from southward to northwardIMF leads to distorted Iwo-celi convection patterns that can contain multiple cellconfigurations.
JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 97, NO. A12. PAGES 19,461-19.469. DECEMBER 1 9"2
East-West Ion Drifts at Mid-Latitudes Observed byDynamics Explorer 2
R. A. HEELis AND W. R. COLEY
Catter for Space Sciences, Physics Program, Universuy of Texas at Dallas, Richardron
Zonal ion drifts measured from the the polar orbiting DE 2 spacecraft are examined to determine the effects ofdynamo electric fields and penetration of high latitude electric fields at middle latitudes. Construction ofs localtime distribution from satellite data results in a mixture of local time and season as well as a range of magnetic activ-ity encompassing Kp <2 and Kp z3. Thus some combination of magnetospheric effects, expected to dominateduring disturbed times, are seen during both quiet and disturbed times and solar tidal influences are most easily ob-served during quiet times. During quiet times, at invariant latitudes near 25*, the solar diurnal tide domunates thelocal time distribution of the ion drift. At latitudes above 50" a diurnal component of comparable magnitude is alsopresent, but its magnetospheric origin produces a shift in phase of almost 180' from the lower latitude diurnal tide.In the intervening region, between 20' and 50' invariant latitude, semidiurnal and terdiurnal components in thelocal time distribution of the drift velocity are also seen. These components are generally larger than those seen byground based radarsduring quiet times and may be attributable in part to a difference i n solar activity and in part to acombination of the solar tides and magnetospheric penetration fields.
17
JOURNAL OF GEOPHYSICAL RESEARCH. V(4)l- '7. No) A9. P[-\(,tS ½i•4I, SEFPTl-.I il.R t I"A
Three-Dimensional Ionospheric Plasma Circulation
R. A HEELiS AND W R. COLEY
Physics Prvgrun, Center for Space Sciences, University of Te=as at Dallas. Richardson
M. LoRANc
Space Sciences Laboratory, NASA Marshall Space Flight Cenze, Huntsville, Alabama
M. R. HAMSTON
Physi•c Prognzmn, Center for Space Sciences. Univeray of Teaw at Dalda" Richardson
Exnminationof the ion driftvelocityvector measured on the DE 2 spacecraft reveals the significance ofionospheric flows both perpendicular and parallel to the magnetic field at high latitudes. Durng periods of
southwarddirected interplanetarymagnetic field the familiar two-cell onvection pattern perpendicular to themagnetic field is associated with field-aligned moaion predominantly upward in the dayside auroral zone andcusp, and predominantly downward in the polar cap. Frictional heating by convecuon through the neutral gasand beating by energetic particle precipitation are believed to be responsible for the bulk of the upward flowwith downward flows resulting from subsequent oooling of the plasma. Some of the upward flowing plasma isapparently given escape energy at altitudes above about 800 km. The average flow of ions across the entirehigh-latitude region at 400akm isoutward andcomparable to the energetic ionoutflow observed at much higheraltitudes by DE I.
JOURNAL OF GEOPHYSICAL RESEARCH. VOL. 96, NO. A8. PAGES 14.1 9-14.L;,.4 \L'Gt IF rI 1#'9I
Energy Dissipation in Structured Electrodynamic Environments
R.A. HEELIS
Physics Programs, Center for Space Sciences, University of Texas at Dallas, Richardson
J.F. VICKREY
Geoscience and Engineering Center, SRI International, Menlo Park, California
The coupling of electromagnetic energy into the ionosphere and thermosphere is anessential consideration for understanding the thermal structure and dynamics of theneutral and charged particles at high latitudes. Often the dissipated electromagneticenergy exceeds that deposited by precipitating energetic particles at high latitudes. Itis usually assumed that the profile of the ion Pedersen conductivity determines thealtitude dependence of the energy dissipation rate. Herein we point out the strongaltitude dependence of the energy dissipation rate on the spatial scale sise of the imposedelectric field. To illustrate the importance of such considerations, we show examples ofthe ubiquity of electric field structure in the high-latitude ionosphere; this is particularlyprominent when the interplanetary magnetic field has a northward component. We thenshow quantitatively how the existence of electric field structure with scale sizes of 10 kmor less strongly impacts both the altitude extent over which the electromagnetic energy isdissipated and its partitioning between current systems perpendicular and parallel to themagnetic field.
18
JOURNAL OF GEOPHYSICAL RESEARCH. VOL. 97. NO. All. PAGES 16.855-16,863, NOVEMBER I, 1992
Upflowing Ionospheric Ions in the Auroral Region
G. Lu,' P. H. REIFF,2 T. E. MOORE,3 AND R. A. HEELIS
Observations of upflowing ionospheric ions are obtained nearly simultaneously by DE I and DE 2 over thenightside auroral regions. At low altitudes, the mean value of the net upward ion number flux is of the order of10- cm"2 s 1 . The ionosphere is predominantly 0O, and the flux of ions with energy greater than 5 eV is avery small fraction (less than 1%) of the total ion flux. At high altitudes, the upflowing ions are accelerated bya parallel electric field and heated (with characteristic energies of hundreds of electron volts). Comparingupflowing fluxes at high and low altitudes yields an estimated height of the bottom of the auroral accelerationregion of 1400-1700 km for the region of peak potential drop. This low-altitude acceleration could either befrom a parallel electric field or from perpendicular acceleration. The fluxes at the edges of the arm are mostly H"thus implying a higher-altitude base of the acceleration region at the edges where the potential drop is lower.
JOURNAL1 OF GEOPHYSICAL RESI \ARC(H. VO)L. 9f), No) Alt), PAGES 1-.84--I- ,'.- )tLR I. 10
Coordinated Radar and Optical Measurements of Stable AuroralArcs at the Polar Cap Boundary
E. J. WEBER, J. F. VICKREY2,- H. GALLAGHER., L. WuLss. C. J. HtItS, MAN-
R. A. HEELIS.' AND M. C. KEt.LENV
A specialized incoherent scatter radar scanning mode has been developed for use in conjunctionwith simultaneous real-time all-sky images. These complementary diagnostics are used to evamine theaeronomy and electrodynamics of stable auroral arcs that delineate the boundary bets•een the polar
cap and the auroral oval. The first arc discussed, observed at 2000 MLT. represents ihe boundarybetween antisunward plasma flow in the polar cap and sunward return flow equator'.ard of the arc
The arc defined an equipotential in the high-latitude convection pattern in ihat no plasma flowed acrossthe arc. The radar line-of-sight velocity measurements also indicate that this arc is consistent vIih aiconvergent electric field and an associated weak upward field-aligned current. The ,econd arc %%a,observed at 2330 MLT and was associated with a nightside gap or magnetic reconnection reialon.Strong antisunward flow was observed directly across the arc, although a selocils .hear "...,,superposed on this steady flow along the poleward edge of the arc. Detailed plama densit,,temperature. and line-of-sight velocity measurements from the radar are presented tor both arc" to
define the electric field, horizontal and field-aligned currents. and thermal plasmna parametersassociated with these arcs.
19
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